Direct current electric transmission system



July 20, 1954 F. BUSEMANN 2,684,461

DIRECT CURRENT ELECTRIC TRANSMISSION SYSTEM Filed Feb. 29, 1952 IN WIN 70/? ATTORNEY Patented July 20, 1954 ITED STATES PATENT FIQE DIRECT CURRENT ELECTRIC TRANSMISSION SYSTEM of Great Britain Application February 29, 1952-, Serial No. 274,260

Claims priority, application Great Britain March 6, 1951 1 3 Claims.

This invention relates to high voltage direct current electric power transmission systems of the type in which valve converters connected. in double path arrangement serve to rectify alternating current from a mains supply transformer so as to provide direct current for the transmission line, and further valve converters connected in a corresponding manner at the far end or the line serve to invert the direct current and provide alternating current at the desired point.

In such systems, power is transmitted over the direct current line at voltages of the order of 100,050 volts with power of the order of 100,000 kilowatts. The valve converters are usually of the mercury-vapour type connected in three-phase bridge arrangement, both at the rectifying end. and also at the inverting end. Thus each set comprises three pairs of converters connected anode to cathode, one pair for each transformer phase.

In general, a two conductor line is employed with the intermediate or mid point earthed, so that there is one set of six converters between one line conductor and. the mid point, and a further set between. and mid point and the other lin conductor. Each set is fed from a threephase transformer with each phase of the secondary winding connected to the interconnected anode cathode of one pair of converters. Choke coils for smoothing ripples are connected in both conductors, both at the rectifier and inverter ends, the converte's are provided with. control and. timing circuits connected to their grids in the usual way.

The provision of circuit breakers for the required direct current voltages is not as simple as that of circuit breakers for alternating current since in the former case, the current does not pass through zero values at which the circuit can be effectively interrupted. On straight transmission lines with no interconnections, however, interruption of the direct current by grid control. of the converters goes long way towards performing the function of circuit breakers.

Grid blocking prevents the setting up of further grid impulses, but it cannot interrupt the current in the converters which are already carrying current at the time when grid blocking occurs. That current continues to flow until it reaches a zero value, but negative current cannot flow because the converters are incapable of reversing. However, the current usually very soon attains a zero value because after occurrence of grid blocking, there is an alternating voltage effective across the converters as long as the current flows. This alternating voltage, of which usually only the portion around the 2 positive peak is utilised for setting up the direct current voltage, is left on the line also during the negative portion and very soon brings down the voltage to zero although with smoothing coils of very large inductance, it may take several cycles for the current to reach a zero value.

At that instant, the flow of current in the converters is interrupted and the grid blocking prevents the rectifier from sending out any more current. This action taking place at the rectifier has no immediate effect on the operation of the inverter. Thus the instant that the current is interrupted at the rectifier, it is very likely that the inverter still carries considerable current. Then the inductance of the smoothing coils at the inverter end, which is usually large, maintains the current which is drawn as a discharge current from the capacitance of the line so that the line voltage is considerably reduced and may even swing over to negative. If the capacitance of the line is small relatively to the inductance of the smoothing coils in terms of the energy stored at rated values, it is possible for the line voltage to acquire a high negative value and to cause damage.

In order to prevent the occurrence of such high voltages on the line after grid blocking, it is the usual practice to connect across the line, valves which lay-pass the rectifier converters and are grid-controlled so that they are blocked during normal operation of the system but are opened or released a soon as the main converters are blocked. Such by-pass valves in the case of hridge-connected rectifiers are connected across the outer line terminals on the rectifier side of the smoothing coils. The by-pass valves are blocked. during normal operation because when the rectifier voltage is very much reduced by phase-control, -tor example, on starting or on the occurrence of faults, and the voltage wave therefore is utilised in the parts around the zero, the voltage on the rectifier side of the smoothing coil becomes negative during a part of the intervals between ignitions of the converters. The result which. it is intended should be produced by the phase control would therefore be partially cancelled. hy the lay-pass valve if it were not blocked during normal operation.

According to the present invention, instead of providing grid-controlled hy-pass valves on the rectifying side of the smoothing coils, an uncontrolled unidirectionally conducting lay-pass path is connected between each line conductor and earth on the side of the smoothing inductors remote from the rectifying installation and this path is connected in such direction as to carry current if the polarity of the line becomes reversed under fault conditions. Preferably, a

' acquiring the opposite polarity.

converter of the same type as is used in the rectifying installation is used to provide the unidirectional characteristic of the by-pass path, but it is possible to use simpler valve devices, such as electrolytic rectifiers, so long as they can carry the current surges which have to pass occasionally when the by-pass path becomes active.

This novel form of connection has several advantages. Thus such an uncontrolled hy-pass is more reliable in action than a controlled valve, since it is not dependent on the proper working of the control equipment and is simplified by avoidance of the need for any connection to the control equipment.

Again, the connection of the by-pass valve directly to the line establishes a fixed lower level of voltage below which the line voltage cannot pass and the valve also prevents the line from This limitation o lower voltage level is of advantage when successive restrilrings of the converters occur as, for example, during starting when the rectifier and the inverter go alternately on the line. Fur-- thermo a lay-pass on the line side of the smooth educes the time or" dissipating the energ n the circuit since the portion stored in the induc ance of the rectifier smootl coil can taken back into the alternating nt supply system during the negative half wave the alternating voltage which would not take place with a by-pass valve connected on the rectifier ide of the smoothing coil.

A system in accordance with the invention will now be described in more detail with reference to the accompanying circuit diagram. The supply is taken from three-phase alternating current mains l i to a transformer ii, the primary windor" which are connected in delta and the secondary wii .ings in star. A circuit breaker It is provided to isolate the transformer from the mains ii. Each phase of the secondary winding of the transformer is connected to the midpoint s y "en pairs of mercury vapour converters i and l, 3 and ii and 5 and 2. The converters of each p ir are connected anode to cathode between an inte ediate point constituted by a busbar l3 '1 i9 and a positive line conductor IE. hole equipment is duplicated between the line conductor and. the intermediate he pro sion of a second transformer a see o d set of six converters, and since this cal with that shown, it is not illusof the converters have timed impulses an 7. o e manner by means of a control unit shown. diagrammatically 25 and energised by way of an auxilia y transformer 2? L" .s i l These iinpu'ses are applied to sequence or" their reference nuonverter i fires first, followed at ty electrical degrees of the alter rter 2 and then by are provided with smoothing inductors M3. Between the positive line conductor 55 and the intermediate point ill and on the side of the smoothing inouctor remote from the rectifying installation, a icy-pass path is connected, comprising a 1 the converters l to 5 "s The of the converter is connected to its cathode by way of a resistance 5i and, in addition, a resistance 52 is connected in the by-pass path.

Under normal conditions the valve action of the converter 51! prevents current flowing between the line conductor [6 and earth, but as soon as the polarity is reversed, a current controlled by the resistan e is allowed to flow, with the result already described.

It the line is a long one its own resistance is sufficient and the resistance 52 may be omitted. In the case of a short line, however, the resistance 52 is useful in dissipating the stored energy in the circuit, particularly in the smoothing inductor 40. In a case, a resistance of the order of one tenth of the rated line-to-earth voltage divided by the rated line current, should be used.

I claim:

1. In a rectifying installation for a high voltage direct current electric power transmission system, the corn -ation of a niulti-phase alternating current stipply, a inulti-phase power transformer having its primary winding connected to said alternating current supply, a pair of direct current terminals, a plurality of pairs of rectifier units connected anode to cathode between said ter als, the phase cornections of the secondary :l .ing of said tran .orrner being connected bets. on the cl-points of said pairs or" rectifier units, oonirn tailing means for said rectifier units, line conductor connected to one of said terminals, a smoothing inductor connected in said conductor, and an uncontrolled, unidirectionally conduct ng my-pass path connected beween the other of said direct current terminals ne conductor at point the side of lg inductor remote from said rectifier units, d loy-pass path being connected in such a direction as to prev the flow rectified current therein f on: rectifier units during normal operation but to carry current ii the polarity of the direct current ininals becomes in der "ault con 2. in rec yi L- stallation for high voltage direct current electric power ti 'ssion system, the combination of a three phase lternating current supply, a three phase power transformer having" its primary nding connected to said alternating cu rent su ply, pair of direct current terminals, three 1* as of mercury vapour rectifies ct oected anode to cathode between said terniinals, the phase connections of the secondary winding of transformerng connected between the mid-points of said pairs of rectlfiers, grid control means for said rectifiers, l ne conductor connected to one of terminals, a smoothing inductor connected in conductor and a further mercury vapour rectifier connected between the other of said curr nt terminals said line c duster at a point on the of smoothing l iduotor remote from said pairs of rectifiers, said further root r ha. ng its anode connected to the sa e direct ouirent teroinal as the anode-s of s: i pairs or" rectifiers having its grid connected to its cathode.

3. A rectifying installation according to claim 2, compri i g -h addition a resistance connected in series with said further mercury vapour reotifier between the other or" said direct current terninals and said line conductor.

References tilted in the file of tn 

